ref: 0aae832ac3f3ae5d136563e980e9c32ceb0d1444
dir: /sys/src/boot/zynq/mmc.c/
#include <u.h> #include "dat.h" #include "fns.h" #include "mem.h" enum { Sectsz = 0x200, Dirsz = 0x20, Maxpath = 64, Fat12 = 1, Fat16 = 2, Fat32 = 4, }; typedef struct File File; typedef struct Dir Dir; typedef struct Pbs Pbs; typedef struct Pbs32 Pbs32; typedef struct Fat Fat; struct Fat { ulong ver; ulong clustsize; ulong eofmark; ulong partlba; ulong fatlba; ulong dirstart; /* LBA for FAT16, cluster for FAT32 */ ulong dirents; ulong datalba; }; struct File { Fat *fat; ulong lba; ulong clust; ulong lbaoff; ulong len; uchar *rp; uchar *ep; uchar buf[Sectsz]; }; struct Dir { char name[11]; uchar attr; uchar reserved; uchar ctime; uchar ctime[2]; uchar cdate[2]; uchar adate[2]; uchar starthi[2]; uchar mtime[2]; uchar mdate[2]; uchar startlo[2]; uchar len[4]; }; struct Pbs { uchar magic[3]; uchar version[8]; uchar sectsize[2]; uchar clustsize; uchar nreserv[2]; uchar nfats; uchar rootsize[2]; uchar volsize[2]; uchar mediadesc; uchar fatsize[2]; uchar trksize[2]; uchar nheads[2]; uchar nhidden[4]; uchar bigvolsize[4]; uchar driveno; uchar reserved0; uchar bootsig; uchar volid[4]; uchar label[11]; uchar type[8]; }; struct Pbs32 { uchar common[36]; uchar fatsize[4]; uchar flags[2]; uchar ver[2]; uchar rootclust[4]; uchar fsinfo[2]; uchar bootbak[2]; uchar reserved0[12]; uchar driveno; uchar reserved1; uchar bootsig; uchar volid[4]; uchar label[11]; uchar type[8]; }; enum { Initfreq = 400000, /* initialisation frequency for MMC */ SDfreq = 25000000, /* standard SD frequency */ DTO = 14, /* data timeout exponent (guesswork) */ }; enum { /* Controller registers */ Sysaddr = 0x00>>2, Blksizecnt = 0x04>>2, Arg1 = 0x08>>2, Cmdtm = 0x0c>>2, Resp0 = 0x10>>2, Resp1 = 0x14>>2, Resp2 = 0x18>>2, Resp3 = 0x1c>>2, Data = 0x20>>2, Status = 0x24>>2, Control0 = 0x28>>2, Control1 = 0x2c>>2, Interrupt = 0x30>>2, Irptmask = 0x34>>2, Irpten = 0x38>>2, Capabilites = 0x40>>2, Forceirpt = 0x50>>2, Boottimeout = 0x60>>2, Dbgsel = 0x64>>2, Spiintspt = 0xf0>>2, Slotisrver = 0xfc>>2, /* Control0 */ Dwidth4 = 1<<1, Dwidth1 = 0<<1, /* Control1 */ Srstdata = 1<<26, /* reset data circuit */ Srstcmd = 1<<25, /* reset command circuit */ Srsthc = 1<<24, /* reset complete host controller */ Datatoshift = 16, /* data timeout unit exponent */ Datatomask = 0xF0000, Clkfreq8shift = 8, /* SD clock base divider LSBs */ Clkfreq8mask = 0xFF00, Clkfreqms2shift = 6, /* SD clock base divider MSBs */ Clkfreqms2mask = 0xC0, Clkgendiv = 0<<5, /* SD clock divided */ Clkgenprog = 1<<5, /* SD clock programmable */ Clken = 1<<2, /* SD clock enable */ Clkstable = 1<<1, Clkintlen = 1<<0, /* enable internal EMMC clocks */ /* Cmdtm */ Indexshift = 24, Suspend = 1<<22, Resume = 2<<22, Abort = 3<<22, Isdata = 1<<21, Ixchken = 1<<20, Crcchken = 1<<19, Respmask = 3<<16, Respnone = 0<<16, Resp136 = 1<<16, Resp48 = 2<<16, Resp48busy = 3<<16, Multiblock = 1<<5, Host2card = 0<<4, Card2host = 1<<4, Autocmd12 = 1<<2, Autocmd23 = 2<<2, Blkcnten = 1<<1, Dmaen = 1<<0, /* Interrupt */ Acmderr = 1<<24, Denderr = 1<<22, Dcrcerr = 1<<21, Dtoerr = 1<<20, Cbaderr = 1<<19, Cenderr = 1<<18, Ccrcerr = 1<<17, Ctoerr = 1<<16, Err = 1<<15, Cardintr = 1<<8, Cardinsert = 1<<6, Readrdy = 1<<5, Writerdy = 1<<4, Dmaintr = 1<<3, Datadone = 1<<1, Cmddone = 1<<0, /* Status */ Present = 1<<18, Bufread = 1<<11, Bufwrite = 1<<10, Readtrans = 1<<9, Writetrans = 1<<8, Datactive = 1<<2, Datinhibit = 1<<1, Cmdinhibit = 1<<0, Inittimeout = 15, // Multiblock = 1, /* Commands */ GO_IDLE_STATE = 0, ALL_SEND_CID = 2, SEND_RELATIVE_ADDR= 3, SELECT_CARD = 7, SD_SEND_IF_COND = 8, SEND_CSD = 9, STOP_TRANSMISSION= 12, SEND_STATUS = 13, SET_BLOCKLEN = 16, READ_SINGLE_BLOCK= 17, READ_MULTIPLE_BLOCK= 18, WRITE_BLOCK = 24, WRITE_MULTIPLE_BLOCK= 25, APP_CMD = 55, /* prefix for following app-specific commands */ SET_BUS_WIDTH = 6, SD_SEND_OP_COND = 41, /* Command arguments */ /* SD_SEND_IF_COND */ Voltage = 1<<8, Checkpattern = 0x42, /* SELECT_CARD */ Rcashift = 16, /* SD_SEND_OP_COND */ Hcs = 1<<30, /* host supports SDHC & SDXC */ Ccs = 1<<30, /* card is SDHC or SDXC */ V3_3 = 3<<20, /* 3.2-3.4 volts */ /* SET_BUS_WIDTH */ Width1 = 0<<0, Width4 = 2<<0, /* OCR (operating conditions register) */ Powerup = 1<<31, }; static int cmdinfo[64] = { [0] Ixchken, [2] Resp136, [3] Resp48 | Ixchken | Crcchken, [6] Resp48 | Ixchken | Crcchken, [7] Resp48busy | Ixchken | Crcchken, [8] Resp48 | Ixchken | Crcchken, [9] Resp136, [12] Resp48busy | Ixchken | Crcchken, [13] Resp48 | Ixchken | Crcchken, [16] Resp48, [17] Resp48 | Isdata | Card2host | Ixchken | Crcchken | Dmaen, [18] Resp48 | Isdata | Card2host | Multiblock | Blkcnten | Ixchken | Crcchken | Dmaen, [24] Resp48 | Isdata | Host2card | Ixchken | Crcchken | Dmaen, [25] Resp48 | Isdata | Host2card | Multiblock | Blkcnten | Ixchken | Crcchken | Dmaen, [41] Resp48, [55] Resp48 | Ixchken | Crcchken, }; typedef struct Ctlr Ctlr; struct Ctlr { u32int *regs; ulong extclk; /* SD card registers */ u16int rca; u32int ocr; u32int cid[4]; u32int csd[4]; }; static Ctlr ctlr = { .regs = (u32int*)0xE0101000, .extclk = 100000000, }; static ushort GETSHORT(void *v) { uchar *p = v; return p[0] | p[1]<<8; } static ulong GETLONG(void *v) { uchar *p = v; return p[0] | p[1]<<8 | p[2]<<16 | p[3]<<24; } static int memcmp(void *src, void *dst, int n) { uchar *d = dst; uchar *s = src; int r = 0; while(n-- > 0){ r = *d++ - *s++; if(r != 0) break; } return r; } static uint clkdiv(uint d) { uint v; v = (d << Clkfreq8shift) & Clkfreq8mask; v |= ((d >> 8) << Clkfreqms2shift) & Clkfreqms2mask; return v; } static int mmcwait(int mask) { int i, t; t = 0; while(((i=ctlr.regs[Interrupt])&mask) == 0) if(t++ > 10000000) break; return i; } static int mmccmd(u32int cmd, u32int arg, u32int *resp) { u32int *r; u32int c; int i; c = (cmd << Indexshift) | cmdinfo[cmd]; r = ctlr.regs; if(r[Status] & Cmdinhibit){ print("mmc: need to reset Cmdinhibit intr %x stat %x\n", r[Interrupt], r[Status]); r[Control1] |= Srstcmd; while(r[Control1] & Srstcmd) ; while(r[Status] & Cmdinhibit) ; } if((c & Isdata || (c & Respmask) == Resp48busy) && r[Status] & Datinhibit){ print("mmc: need to reset Datinhibit intr %x stat %x\n", r[Interrupt], r[Status]); r[Control1] |= Srstdata; while(r[Control1] & Srstdata) ; while(r[Status] & Datinhibit) ; } r[Arg1] = arg; if((i = r[Interrupt]) != 0){ if(i != Cardinsert) print("mmc: before command, intr was %x\n", i); r[Interrupt] = i; } r[Cmdtm] = c; i = mmcwait(Cmddone|Err); if((i&(Cmddone|Err)) != Cmddone){ if((i&~Err) != Ctoerr) print("mmc: CMD%d error intr %x stat %x\n", cmd, i, r[Status]); r[Interrupt] = i; if(r[Status]&Cmdinhibit){ r[Control1] |= Srstcmd; while(r[Control1]&Srstcmd) ; } return -1; } r[Interrupt] = i & ~(Datadone|Readrdy|Writerdy); switch(c & Respmask){ case Resp136: resp[0] = r[Resp0]<<8; resp[1] = r[Resp0]>>24 | r[Resp1]<<8; resp[2] = r[Resp1]>>24 | r[Resp2]<<8; resp[3] = r[Resp2]>>24 | r[Resp3]<<8; break; case Resp48: case Resp48busy: resp[0] = r[Resp0]; break; case Respnone: resp[0] = 0; break; } if((c & Respmask) == Resp48busy){ r[Irpten] = Datadone|Err; i = mmcwait(Cmddone|Err); if(i) r[Interrupt] = i; r[Irpten] = 0; if((i & Datadone) == 0) print("mmc: no Datadone after CMD%d\n", cmd); if(i & Err) print("mmc: CMD%d error interrupt %x\n", cmd, i); } /* * Once card is selected, use faster clock */ if(cmd == SELECT_CARD){ sleep(10); r[Control1] = clkdiv(ctlr.extclk / SDfreq - 1) | DTO << Datatoshift | Clkgendiv | Clken | Clkintlen; for(i = 0; i < 1000; i++){ sleep(1); if(r[Control1] & Clkstable) break; } sleep(10); } /* * If card bus width changes, change host bus width */ if(cmd == SET_BUS_WIDTH) switch(arg){ case 0: r[Control0] &= ~Dwidth4; break; case 2: r[Control0] |= Dwidth4; break; } return 0; } static int mmconline(void) { u32int r[4]; int hcs, i; mmccmd(GO_IDLE_STATE, 0, r); hcs = 0; if(mmccmd(SD_SEND_IF_COND, Voltage|Checkpattern, r) == 0){ if(r[0] == (Voltage|Checkpattern)) /* SD 2.0 or above */ hcs = Hcs; } for(i = 0; i < Inittimeout; i++){ sleep(100); mmccmd(APP_CMD, 0, r); mmccmd(SD_SEND_OP_COND, hcs|V3_3, r); if(r[0] & Powerup) break; } if(i == Inittimeout){ print("mmc: card won't power up\n"); return -1; } ctlr.ocr = r[0]; mmccmd(ALL_SEND_CID, 0, r); memcpy(ctlr.cid, r, sizeof ctlr.cid); mmccmd(SEND_RELATIVE_ADDR, 0, r); ctlr.rca = r[0]>>16; mmccmd(SEND_CSD, ctlr.rca<<Rcashift, r); memcpy(ctlr.csd, r, sizeof ctlr.csd); mmccmd(SELECT_CARD, ctlr.rca<<Rcashift, r); mmccmd(SET_BLOCKLEN, Sectsz, r); mmccmd(APP_CMD, ctlr.rca<<Rcashift, r); mmccmd(SET_BUS_WIDTH, Width4, r); return 0; } static int mmcinit(void) { u32int *r; int i; r = ctlr.regs; r[Control1] = Srsthc; for(i = 0; i < 100; i++){ sleep(10); if((r[Control1] & Srsthc) == 0) break; } if(i == 100){ print("mmc: reset timeout!\n"); return -1; } r[Control1] = clkdiv(ctlr.extclk / Initfreq - 1) | DTO << Datatoshift | Clkgendiv | Clken | Clkintlen; for(i = 0; i < 1000; i++){ sleep(1); if(r[Control1] & Clkstable) break; } if(i == 1000){ print("mmc: SD clock won't initialise!\n"); return -1; } r[Irptmask] = ~(Dtoerr|Cardintr|Dmaintr); return mmconline(); } static int mmcread(ulong bno, uchar buf[Sectsz]) { u32int *r, rr[4]; int i, t; r = ctlr.regs; for(t=0; t<3; t++){ r[Sysaddr] = (u32int)buf; r[Blksizecnt] = 7<<12 | 1<<16 | Sectsz; r[Irpten] = Datadone|Err; mmccmd(READ_SINGLE_BLOCK, ctlr.ocr & Ccs? bno : bno*Sectsz, rr); i = mmcwait(Datadone|Err); if(i) r[Interrupt] = i; r[Irpten] = 0; if((i & Err) != 0) print("mmcread: error intr %x stat %x\n", i, r[Status]); else if((i & Datadone) == 0) print("mmcread: timeout intr %x stat %x\n", i, r[Status]); else return 0; } return -1; } static int dirname(Dir *d, char buf[Maxpath]) { char c, *x; if(d->attr == 0x0F || *d->name <= 0) return -1; memcpy(buf, d->name, 8); x = buf+8; while(x > buf && x[-1] == ' ') x--; if(d->name[8] != ' '){ *x++ = '.'; memcpy(x, d->name+8, 3); x += 3; } while(x > buf && x[-1] == ' ') x--; *x = 0; x = buf; while(c = *x){ if(c >= 'A' && c <= 'Z'){ c -= 'A'; c += 'a'; } *x++ = c; } return x - buf; } static ulong dirclust(Dir *d) { return GETSHORT(d->starthi)<<16 | GETSHORT(d->startlo); } static void fileinit(File *fp, Fat *fat, ulong lba) { fp->fat = fat; fp->lba = lba; fp->len = 0; fp->lbaoff = 0; fp->clust = ~0U; fp->rp = fp->ep = fp->buf + Sectsz; } static ulong readnext(File *fp, ulong clust) { Fat *fat = fp->fat; uchar tmp[2], *p; ulong idx, lba; if(fat->ver == Fat12) idx = (3*clust)/2; else idx = clust*fat->ver; lba = fat->fatlba + (idx / Sectsz); if(mmcread(lba, fp->buf)) memset(fp->buf, 0xff, Sectsz); p = &fp->buf[idx % Sectsz]; if(p == &fp->buf[Sectsz-1]){ tmp[0] = *p; if(mmcread(++lba, fp->buf)) memset(fp->buf, 0xff, Sectsz); tmp[1] = fp->buf[0]; p = tmp; } if(fat->ver == Fat32) return GETLONG(p) & 0xfffffff; idx = GETSHORT(p); if(fat->ver == Fat12){ if(clust & 1) idx >>= 4; idx &= 0xfff; } return idx; } static int fileread(File *fp, void *data, int len) { Fat *fat = fp->fat; if(fp->len > 0 && fp->rp >= fp->ep){ if(fp->clust != ~0U){ if(fp->lbaoff % fat->clustsize == 0){ if(fp->clust < 2 || fp->clust >= fat->eofmark) return -1; fp->lbaoff = (fp->clust - 2) * fat->clustsize; fp->clust = readnext(fp, fp->clust); fp->lba = fp->lbaoff + fat->datalba; } fp->lbaoff++; } if(mmcread(fp->lba++, fp->rp = fp->buf)) return -1; } if(fp->len < len) len = fp->len; if(len > (fp->ep - fp->rp)) len = fp->ep - fp->rp; memcpy(data, fp->rp, len); fp->rp += len; fp->len -= len; return len; } static int fatwalk(File *fp, Fat *fat, char *path) { char name[Maxpath], *end; int i, j; Dir d; if(fat->ver == Fat32){ fileinit(fp, fat, 0); fp->clust = fat->dirstart; fp->len = ~0U; }else{ fileinit(fp, fat, fat->dirstart); fp->len = fat->dirents * Dirsz; } for(;;){ if(fileread(fp, &d, Dirsz) != Dirsz) break; if((i = dirname(&d, name)) <= 0) continue; while(*path == '/') path++; for(end = path; *end != '\0'; end++) if(*end == '/') break; j = end - path; if(i == j && memcmp(name, path, j) == 0){ fileinit(fp, fat, 0); fp->clust = dirclust(&d); fp->len = GETLONG(d.len); if(*end == 0) return 0; else if(d.attr & 0x10){ fp->len = fat->clustsize * Sectsz; path = end; continue; } break; } } return -1; } static int conffat(Fat *fat, void *buf) { Pbs *p = buf; uint fatsize, volsize, datasize, reserved; uint ver, dirsize, dirents, clusters; if(GETSHORT(p->sectsize) != Sectsz) return -1; if(memcmp(p->type, "FAT", 3) && memcmp(((Pbs32*)buf)->type, "FAT", 3)) return -1; /* load values from fat */ ver = 0; fatsize = GETSHORT(p->fatsize); if(fatsize == 0){ fatsize = GETLONG(((Pbs32*)buf)->fatsize); ver = Fat32; } volsize = GETSHORT(p->volsize); if(volsize == 0) volsize = GETLONG(p->bigvolsize); reserved = GETSHORT(p->nreserv); dirents = GETSHORT(p->rootsize); dirsize = (dirents * Dirsz + Sectsz - 1) / Sectsz; datasize = volsize - (reserved + fatsize * p->nfats + dirsize); clusters = datasize / p->clustsize; if(ver != Fat32) if(clusters < 0xff7) ver = Fat12; else ver = Fat16; /* fill FAT descriptor */ fat->ver = ver; fat->dirents = dirents; fat->clustsize = p->clustsize; fat->fatlba = fat->partlba + reserved; fat->dirstart = fat->fatlba + fatsize * p->nfats; if(ver == Fat32){ fat->datalba = fat->dirstart; fat->dirstart = GETLONG(((Pbs32*)buf)->rootclust); fat->eofmark = 0xffffff7; }else{ fat->datalba = fat->dirstart + dirsize; if(ver == Fat16) fat->eofmark = 0xfff7; else fat->eofmark = 0xff7; } return 0; } static int findfat(Fat *fat, ulong xbase, ulong lba) { struct { uchar status; uchar bchs[3]; uchar typ; uchar echs[3]; uchar lba[4]; uchar len[4]; } p[4]; uchar buf[Sectsz]; int i; if(xbase == 0) xbase = lba; if(mmcread(lba, buf)) return -1; if(buf[0x1fe] != 0x55 || buf[0x1ff] != 0xAA) return -1; memcpy(p, &buf[0x1be], sizeof(p)); for(i=0; i<4; i++){ switch(p[i].typ){ case 0x05: case 0x0f: case 0x85: /* extended partitions */ if(!findfat(fat, xbase, xbase + GETLONG(p[i].lba))) return 0; /* no break */ case 0x00: continue; default: fat->partlba = lba + GETLONG(p[i].lba); if(mmcread(fat->partlba, buf)) continue; if(!conffat(fat, buf)) return 0; } } return -1; } static int load(Fat *fat, char *path, void *data) { uchar *p; File fi; int n; print("%s", path); if(fatwalk(&fi, fat, path)){ print(": not found\n", path); return -1; } print("..."); p = data; while((n = fileread(&fi, p, Sectsz)) > 0) p += n; print("\n"); return p - (uchar*)data; } int mmcboot(void) { char file[Maxpath], *p; Fat fat; if(mmcinit() < 0) return 0; if(findfat(&fat, 0, 0)){ print("no fat\n"); return 0; } memcpy(file, "9zynq", 6); memset(p = (char*)CONF, 0, CONFSIZE); p += load(&fat, "plan9.ini", p); p -= 9; /* "bootfile=" */ while(--p >= (char*)CONF){ while(p > (char*)CONF && p[-1] != '\n') p--; if(memcmp("bootfile=", p, 9) == 0){ p += 9; memcpy(file, p, sizeof(file)-1); for(p=file; p < &file[sizeof(file)-1]; p++) if(*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n') break; *p = '\0'; break; } } return load(&fat, file, (void*)TZERO) > 0; }